and rotational inertia We consider the rotation of rigid bodies A rigid body is an extended object in which the mass is distributed spatially Where should a force be applied to make it rotate spin The same force applied at ID: 567291
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Slide1
L-10(M-9) torque and rotational inertia
We consider the rotation of rigid bodies. A rigid body is an extended object in which the mass is distributed spatially.Where should a force be applied to make it rotate (spin)? The same force applied at different locations produces different results.
1
AXLESlide2
TORQUE – Greek letter tau t
To make an object rotate, a force must be applied in the right place.the combination of force and point of application is called TORQUEThe
lever arm L is the distance from the axis of rotation to the point where the force is appliedIf the line of action of F passes through the axis of rotation, it produces no torque.
Force, F
lever
arm:
L
Axis
2Slide3
force F in
Newtons,
Nlever arm L in meters, m
Torque t in units of N mTorque: t (Greek tau) Torque = force (F) x lever arm (L)t = F L
3Slide4
Torque example
F
L
What is the torque on a bolt
applied with a wrench that
has a lever arm: L= 20 cm
with a force: F = 30 N?
Solution:
t
=
F
L = 30 N (1/5) m = 6 N m
For the same force, you get more torquewith a bigger wrench the job is easier!
4Slide5
Torque wrench
5
A torque wrench is a wrench that applies
a calibrated torque to a bolt.It prevents a bolt from being over-tightenedand possibly breaking.Slide6
Homer attempts to straighten out the leaning tower of Pisa
fulcrum
lever
6Slide7
Net Force = 0 , Net Torque ≠ 0
10 N
10 N
> The net force = 0, since the forces are applied in
opposite directions so it will not accelerate.
> However, together these forces will make the rod
rotate in the clockwise direction.
7Slide8
Net torque = 0, net force ≠ 0
The rod will accelerate upward under these
two forces, but will not rotate.
8Slide9
Balancing torques
10 N
20 N
1 m
0.5 m
Left torque = 10 N x 1 m = 10 n m
Right torque = 20 N x 0.5 m = 10 N m
9Slide10
Equilibrium
To ensure that an object does not accelerate or rotate two conditions must be met: net force = 0 net torque = 0
this results in the practical 4-1 “ladder rule”
10Slide11
When is an object stable?
If you can tip it over a bit and it doesn’t fallThe object may wobble a bit but it eventually stops and settles down to its upright position.
A thinner object is
easier to topple
An object that is thicker
at its base is more stable
11Slide12
Why do tall objects tend to fall over
Every object has a special point called the center of gravity (CG). The CG is usually in the center of the object.if the center of gravity is supported, the object will not fall over.
The lower the CG the more stable an object is. stable not easy to knock over!
12Slide13
Condition for stability
If the CG is above
the
edge of the table, the objectwill not fall off.
CG
13Slide14
Why makes an object tip over?
For the wide object, the dashed line extending from the CG down is to the left of the point of contact; the torque due to the weight tends to rotate the object counterclockwiseFor the narrow object, the dashed line extending from the CG down is to the right of the point of contact, the torque due to the weight tends to rotate the object clockwise.
14
STABLE
UNSTABLE
D
D
CG
CGSlide15
Stable structures
Structures are
wider at their
base to lower their
center of gravity
15Slide16
If the center of gravity
is supported, the blocks
do not fall over
Playing with blocks
CG
16Slide17
Coin Stack
17Slide18
As more stuff is loaded into a semi, its center of gravity moves upward, making it susceptible to tipping over in high winds.
High Profile Vehicles
wind
18Slide19
Rotational Inertia
(moment of inertia) symbol IA rigid body is characterized by a parameter called its rotational inertia
The rotational inertia of a RB depends on how its mass is distributed relative to the axis of rotationThe rotational inertia of a RB is the parameter that is analogous to inertia (mass) for a non-extended object For a RB, the rotational inertia determines how much torque is needed to produce a certain amount of rotational acceleration (spin).
19Slide20
rotational inertia examples
Rods of equal mass m and length L
axis through center
axis through end
20
The rod with the axis through the end requires more torque to get it rotating.Slide21
How fast does it spin?
For spinning or rotational motion, the rotational inertia of an object plays the same role as ordinary mass for simple motionFor a given amount of torque applied to an object, its rotational inertia determines its rotational acceleration the smaller the rotational inertia, the bigger the rotational acceleration
21Slide22
Big rotational
inertia
Small rotational
inertia
Same
torque, different rotational
inertia
spins
slow
spins
fast
22
L = R
F = mg
t =
F L =
mgR